bitumen attack by - American Chemical Society

Achromobacter, Micrococcus, Flavobacterium, Bacillus, Coryne- bacterium, and Alcaligenes. Certain organisms in the genera Mycobacterium and Nocardia ...
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BITUMEN ATTACK BY 1 R. W. Traxler t is generally recognized today that a variety of bitu-

I minous materials are subject to attack by microorganisms (7, 4, 5). Early reports from our laboratory confirm the fact that asphalts are degraded by a variety of bacteria (7, 9). The purpose of this paper is to summarize the extent of our research into the attack of bituminous materials by microorganisms. Most of our studies deal with bituminous materials of petroleum origin and will emphasize the nature of the organisms attacking bitumens, the nature of the microbial action on bitumen, and the asphaltic constituents utilized by bacteria. Asphalt-Utilizing Organisms

A typical paving asphalt (135 penetration) designated as “1A” was used for enrichment culture isolation of bacteria capable of utilizing bitumen. The organisms obtained were members of the genera Pseudomonas, Achromobacter, Micrococcus, Flavobacterium, Bacillus, Corynebacterium, and Alcaligenes. Certain organisms in the genera Mycobacterium and Nocardia grew well on asphalt substrates. These results demonstrate the diversity of microorganisms capable of utilizing a bitumen of this nature. A soil burial test was devised using a variety of bitumens coated on birch tongue blades exposed in soil under natural conditions. One set of blades was buried in a soil with a high moisture content (16%) and a duplicate set in a similar soil but under low moisture AUTHOR Richard W . Traxler is Associate Professor in the Department of Microbiology, University of Southwestern Louisiana. He acknowledges jinancial support from the Petroleum Research Fund of the American Chemical Society to carry out this work. Dr. Traxler also expresses his appreciation to R. N . Traxler of the Texas Transportation Institute for providing the asphalts and asphalt fractions used in the investigations, and for the infrared data on the thermal dtyusion fractions.

(G.4%) conditions. Action was scored by determining the weight loss of the bitumen coat from the tongue blades at varying time intervals. The result of one series of experiments is shown in Figure 1. Bitumen “A” is most susceptible to weight loss in moist soil, followed in order by bitumens “C,” “F,” and “E.” Bitumen “FT” was reported to be treated with a bactericidal material and does not show a weight loss even after 28 weeks of exposure in moist soil. I n dry soil, apparently all of the bitumens except “A” are resistant to weight loss. I t would appear that moisture level is indeed critical ( 3 ) , as pointed out by Harris. Also, bitumens differ in their susceptibility to soil effects. The difference in susceptibility of bitumen to bacterial action is further supported by laboratory experiments ( 9 ) . It was demonstrated that Bacillus 11-2A isolated by enrichment culture would readily attack asphalt GA and utilize bitumens “A” and ‘(E” to a lesser extent, but was unable to utilize asphalt “G.” All of these materials were demonstrated to serve as a growth substrate for a Flavobacterium. This is further evidence for the specificity of action of a bacterium on different bitumens. Some of the characteristics of these materials are presented in Table I, from which it is seen that these materials vary in their physical nature. I t is logical to conclude that the microbial attack on bitumens is specific. The specificity is determined not only by the nature of the bacterium but also by the chemical composition of the bitumen. Nature of Action

The rate of bitumen deterioration under natural conditions can vary to a large extent depending upon the material and the conditions of exposure. It is not the purpose of this paper to dwell upon the conditions of exposure. The weight loss experiments shown in Figure 1 might be considered an index of susceptibility to the microbial populations in the soil. I t is doubtful that the weight loss in these experiments is due entirely to VOL. 5 8

NO. 6 J U N E 1 9 6 6

59

MOIST SOIL

700

-i

DRY SO1 L

500

m VI

/*

0 -1

+

E

c?

300

100

4

12

20

4

28

12

20

TIME (weeks) Figure 7 .

Efect of soil burial on ihe weight loss of bitumen-coated tongue blades

microbial action. Natural weathering effects plus soil absorption could also be involved in this weight loss. However, it is likely that microbial action accounts for the major portion of the loss. Earlier reports (7, 9 ) cite degradative activity of a number of pure cultures on a single asphalt under laboratory conditions. In these experiments the rate of breakdown was rapid, 3 to 25% degradation occurring within 1 week of exposure under optimum conditions of temperature, pH, and aeration. There is a vast difference between the laboratory conditions and the soil burial test in that extremely thin films of asphalt were used in these laboratory experiments and relatively thick films in the soil burial experiments. It is apparent from early experiments that the bacterial attack is only at the surface of the bitumen. With the thin film, most of the bitumen is exposed as a

TABLE I. PROPERTIES OF BITUMEN§ USED IN SOIL BURIAL TESTS AND GROWTH STUDIES Penetration, Bitumen 6A A E G C

F FT

60

Softening Point (. a F.) ,

Gravity,

111 195 167 161 214 170 173

0.985 1.015 1.175 1.269 1.06 1.105 1.226

.-

,

-

_______ 133

48 0 0

3 0 0

INDUSTRIAL A N D ENGINEERING CHEMISTRY

surface and is, therefore, available to the organism. I n the soil burial tests and in use, the bitumen is applied as a relatively thick film; therefore, only a small overall portion of the bitumen is exposed to microbial action. The thin film provides visual evidence for the microbial action. Figure 2 s h o w a flask on the left containing a film of asphalt 1A inoculated with Mycobacterium ranae and on the right, an identical flask without the test organism. After incubation at 30' C. for 1month, the film in the test flask has broken and settled to the bottom, whereas the control film is unchanged. Even more significant is the appearance of asphalt samples from each flask (Figure 3 ) . The test asphalt is dull, rough, crumbly, and has lost its usual rheological characteristics, whereas the sample from the control flask is not changed in its characteristics. Harris and Worley (6) performed a series of experiments to determine the effect of various bacteria on paving asphalts. They used softening point, ductility, and penetration measurements to determine the action of the organisms and concluded that either a softening or hardening of the asphalts occurred, depending on the nature of the bacteria present. T o assess accurately the effect of the organisms, we must attempt to expose the major portion of the asphalt to microbial action. An emulsion system was used, and the asphalts were exposed to Mycobacterium ranae and iVocardia coeliaca at 30' C . for 4 months. The asphalts were recovered and examined for changes in viscosity. Sterile controls were treated in the same manner as the test flasks and used to determine relative viscosity of asphalt degraded by the microorganisms.

Figure 2. Effect of Mycobacterium ranae on asphalt 7 A film. The test flask is on the left, the controljask on the right. The incubation wasfor 7 month at 30° C.

Figure 3. Asphalt samples collected from culture flasks. testflask appears on the left, control cultuie on right

Culture from

Table I1 shows that the net effect of these two organisms was to increase the viscosity of the three asphalts tested. It is significant that the three asphalts investigated vary considerably in their susceptibility to microbial action, as evidenced by the viscosity data. I t is logical to assume that this effect is tied in with the action of the organisms on some asphalt component that is susceptible to microbial action and is also related to the rheological characteristics of these asphalts. The relation between asphalt composition and hardening is not well defined, but some information is now available (8). Considerable evidence has accumulated over the years which shows that asphalts harden with aging when subjected to heat, oxygen, or actinic light. This hardening reduces the adhesiveness and, therefore, the inservice durability of the material. These hardening effects can to a large extent be due to oxidation of certain asphalt components. The effect of microbial action on the asphalt would be expected to involve primarily oxidation of those asphalt components utilized for growth by the microorganism. Table I11 summarizes some preliminary data from studies in our laboratory on those fractions from three asphalts utilized for growth by selected microorganisms. Pseudomonas 19GAa utilizes only the base material from the three asphalts and will not grow on the unfractionated asphalt. Mycobacterium ranae drastically modifies the asphalt (viscosity studies) and utilizes all fractions which have been studied. Nocardia coeliaca, which also has a drastic effect on viscosity, will utilize all fractions tested except the acetone eluate. The base material has a considerable aliphatic hydrocarbon content, as will be pointed out later. Nocardia coeliaca is known to grow on many of the n-alkanes; therefore, it will likely utilize the base material. T o simplify the approach to this problem the asphalts were fractionated into narrow fractions of somewhat similar compounds. The asphaltenes (pentane insoluble) were separated from the petrolenes (pentane soluble) by treatment with n-pentane. The pentane soluble petrolenes were extracted with sulfuric acid followed by chromatographic fractionation on a Florisil column.

TABLE I 11. G R O W T H OF TEST ORGAN ISMS ON ASPHALT AND ASPHALT FRACTIONS Assay Material Asphalt 1A Asphaltenes 1A Acetone eluate 1A Base material 1A

TABLE II. RELATIVE VISCOSITY OF ASPHALTS AFTER M I C R O B I A L ACTION _ I _

Relative Viscositya

-.____~_.____~~___

M . ranae

Asphalt ~

1A 3A 6A a

_______ 2.0 3.3

-

___N . coeliaca

Asphalt 3A Asphaltenes 3A Acetone eluate 3A Base material 3A

1.4 3.8 6.8

viscosity degraded asfihalt Relative viscosity = viscositv control asbhalt. Control asfhalts not exposed io microbi2 action Viscosity calculated at 5 X 10-2 set.-' Rate of shear was approximately 500,000fioises at 25' C.,

1

Ps. 1Q6Aa

M . ranae

-

+ + + + + + + + +

+ -

+

+ +

+ a

+ +-

q:

Asphalt 6A Acetone eluate 6A Rase material 6A a

I N . coeliaca

Q

a

Not tested. VOL. 5 8

NO. 6

JUNE 1 9 6 6

61

The n-pentane eulate from the Florisil column (base material) was further fractionated by thermal diffusion to provide narrow fractionation of the lower molecular weight and less polar portions of the asphalts. Acetone was used further to strip the Florisil column and represents the acetone eluate (Table 111). The base material and 10 thermal diffusion fractions have received the most extensive study to date. Infrared spectrophotometric analyses and microbial growth studies have been performed on these fractions. Figures 4, 5 , and 6 show the infrared spectra of the base material and 10 thermal diffusion fractions from each of the three asphalts studied (lA, 3A, and 6A). I t should be pointed out that Fraction 1 is from the bottom of the column and fraction 10 from the top. All band positions are reported in reciprocal centimeters (cm. -I) and expressed as peak heights relative to those intensities of fraction 1. The fractions from asphalt 1A have considerably more aliphatic character than those from the other two asphalts. There is considerable aromaticity present in the 1A and 3A asphalt fractions. I t is apparent except for fraction 10 of asphalt lA, 3A, and 6A, which are predominantly aliphatic, all these fractions are a mixture of aliphatic and aromatic compounds. Each fraction was assayed for growth supporting activity with Mycobacterium ranae and Pseudomonas 196Aa. Table I V shows the maximum turbidity developing on each fraction in the Pseudomonas 196Aa assays. PJeudomonas will grow only on the top fractions, which are demonstrated to be aliphatic in nature. The infrared data, however, demonstrate the presence of aliphatic materials in all thermal diffusion fractions. The hydrocarbon specificity data (Table V) demonstrate that Pseudomonas 196Aa is limited to the utilization of n-alkanes (C-6 to C-22)) alkenes (C-8, ‘2-10, C-12, and C-14)) as well as certain of the fatty acids. This organism was incapable of growth on any of the aromatic hydrocarbons tested. The decreased growth response of Pseudomonas 196.4a on the base materials from the three asphalts and fraction 9 from asphalts 1A and 3A, as well as the complete absence of growth on fraction 9 of asphalt 6A, is difficult to understand if the organism is capable of utilizing the alkane shown by infrared analyses to be present in these materials (Figures 4, 5 , and 6). It is apparent that the ratio of aromatic material to aliphatic material is greater in those fractions not supporting the growth of Pseudomonas 196Aa than the few fractions which do support growth of this organism. It would appear, therefore, that Pseudomonas 196Aa can

TABLE IV.

Asphalt 1A Asphalt 3A Asphalt 6A a

b

62

= -a0E Ji

B

9 l60OL

AROMATIC C=C

STRETCH

718 BM

1

2

4 5 FRACTIONS

3

7

6

10

9

8

Figure 4. Infrared spectra of base material and thermal difusion fractions from asphalt 7A

I

I

696 ~

-7 --d 1725 0 %z

VI 0

= n ==

~1,3,5

SUBSTITUTED BENZENES

---l

6 1,2,3,4 SUBSTITUTED BENZENES

1600

AROMATIC C=C

71%

i

STRZTCH

FOUR OR MORE METHYLENE GROUPS BM

1

2

3

4

7

5 6 FRACTIONS

8

9

10

Maxamum Turbidztya

~

BMb

3

4

64

0 0 0

0 0

32

Results an Klett unzts after 72-hour zncubatton at 32‘ C. Base materzal. INDUSTRIAL A N D ENGINEERING CHEMISTRY

I

Figure 5. Infrared spectra of base material and thermal d$usion fractions from asphalt 3 A

GROWTH OF Pseudomonos 196Aa ON THERMAL DIFFUSION FRACTIONS

Fract z on Source

-

1

-T -s

7

8

0 0 0

1

9

10

25

116 175 122

58 0

0

TABLE V.

SUBSTRATE SPECIFICITY Pseudomonas 196Aa

OF 696

n-ALKANES I

Hexane Heptane Octane Nonane Decane Dodecane Tridecane Tetradecane Hexadecane Octadecane Eicosane Docosane

175 195 200

229 200 220 230 260 260 200 250 220

s

P

s

718

0 21 0 178 120 300 0

AROMATICS Benzene Ethylbenzene Propylbenzene Trimethylbenzene Pentamethylbenzene Hexamethylbenzene Xylenes (0, m, p ) Toluene

-

1

-

AROMATIC C=C

STRETCH

1

r FOUR OR MORE METHYLENE GROUP§

75 105 115 100 95 183 180 190 260 0

Turbidity in Klett Units

Aromatic Hydrocarbon Control 0. 2Ye Benzene 1 .O’% Benzene 0.2Oj, Toluene 0.2’33 Propylbenzene 1 .O% Propylbenzene 2 . 0 % Propylbenzene 1 .O% Toluene 0 . 2 % Trimethylbenzene 1 .O% Trimethylbenzene 2 . 0 % Trimethylbenzene

FATTY ACIDS Hexanoic Heptanoic Octanoic Nonanoic Decanoic Dodecanoic Tetradecanoic Hexadecanoic Octadecanoic Behenic

1600

1,2,3,4 SUBSTITUTED BENZENES

TABLE V i . EFFECTOF A R O M A T I C HYDROCARBONS O N n-OCTANE U T I L I Z A T I O N B Y Pseudomonas 196Aaa

ALKENES 1-Heptene 1-Octene 1-Decene 1-Dodecene 1-Tetradecene 1-Hexadecene

s t:

1,3,5 SUBSTITUTED BENZENES

a

18 Hr.

20 Hr.

55 40

115 60

0 115 110 5 0

0 180 115 90

0

160 170 15 0 0 200 140 115

2% n-Octane in alljasks.

utilize the n-alkanes (or alkane derivatives) present in the asphalt fractions, but the organism is inhibited in the presence of substituted benzene compounds. The results of the experiment, shown in Table VI, confirm the inhibition of n-alkane oxidation by Pseudomonas 196Aa in the presence of aromatic hydrocarbons. The greater the aromaticity of the compound, the greater the inhibition of n-octane utilization. Benzene was shown to be the most inhibitory compound, followed by toluene, propylbenzene, and, finally, trimethylbenzene, which is not inhibitory. Trimethylbenzene apparently is utilized in the presence of n-octane, but not alone. This effect has not been fully investigated a t this time, but may represent a cooxidation effect (2). The growth response pattern of Mycobacterium ranae on the thermal diffusion fractions (Table VII) is completely different from the Pseudomonas pattern. This organism is capable of growth on all of the asphalt 6A fractions, and most of the 3A and 1A fractions. I t would appear that VOL. 5 % NO. 6 J U N E 1 9 6 6

63

TABLE V I I .

Asphalt 1A Asphalt 3A hsphalt 6A

1

1 1

G R O W T H OF Microbacterium ranae O N T H E R M A L DIFFUSION FRACTIONS

__ 7 0 1 182 202 ~

0

58 26

1

1

82 O

I

"

Mycobacterium ranae is not so selective as Pseudomonas 196Aa in the materials that it can utilize. Examination of the specificity data of this organism for pure hydrocarbons (Table VIII) indicates it is able not only to utilize n-alkanes (C-12 to C-22) but also some alkenes, fatty acids, and all of the aromatic hydrocarbons tested except benzene. I t is concluded from these data that Mycobacterium ranae is utilizing both aromatic and aliphatic hydrocarbons present in the thermal diffusion fractions from these asphalts, whereas Pseudomonas 196Aa grows on only the n-alkanes present in the fractions. A further point is that Pseudomonas 196Aa does not utilize the n-alkane known to be present (infrared data) when the concentration of aromatic hydrocarbon is high. This, in turn, would account for the ability o i Mycobacterium ranae to degrade the unfractionated asphalt, whereas Pseudomonas l96Aa is unable to modify the three asphalts. These data would further indicate that Mycobacterium ranae modifies the aromatic hydrocarbon present in the asphalts, with but minor action on the saturated hydrocarbons. Summary

We have demonstrated that the organisms capable of attacking bitumens are diverse and do not fall into a specific taxonomic group. The microbial action of bitumens shows a specificity that involves both the microorganism and the bituminous substrate. Soil burial tests demonstrate the moisture requirement for microbial action as well as differences in the susceptibility of bituminous materials. I n a limited series of experiments, it was found that the net effect of microbial action on three asphalts was an increase in the viscosity of the asphalts. I t is theorized that the increase in viscosity is due to the oxidation of certain asphalt compounds which are also important in determining the rheological characteristics of the asphalts. Preliminary studies on the components of asphalts utilized by microorganisms indicate that both the aromatic and saturated hydrocarbons are utilized by Mycobacterium ranae. This organism caused a drastic rnodification of the viscosity of three asphalts. I t would appear that this modification in rheological characteristics is caused by oxidation of aromatic and saturated hydrocarbons in the petrolene (pentane-soluble material) fraction of these asphalts. Further studies are to be conducted on the asphaltenes and other fractions from these three asphalts. 64

INDUSTRIAL AND ENGINEERING CHEMISTR'